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Fuzzy expert systems. Fuzzy logic. Introduction, or what is fuzzy thinking? Fuzzy sets Linguistic variables and hedges Operations of fuzzy sets Fuzzy rules Summary. Introduction, or what is fuzzy thinking?. Experts rely on common sense when they solve problems.
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Fuzzy expert systems Fuzzy logic • Introduction, or what is fuzzy thinking? • Fuzzy sets • Linguistic variables and hedges • Operations of fuzzy sets • Fuzzy rules • Summary
Introduction, or what is fuzzy thinking? • Experts rely on common sense when they solve problems. • How can we represent expert knowledge that uses vague and ambiguous terms in a computer? • Fuzzy logic is not logic that is fuzzy, but logic that is used to describe fuzziness. Fuzzy logic is the theory of fuzzy sets, sets that calibrate vagueness. • Fuzzy logic is based on the idea that all things admit of degrees. Temperature, height, speed, distance, beauty all come on a sliding scale. • The motor is running really hot. • Tom is a very tall guy.
Boolean logic uses sharp distinctions. It forces us to draw lines between members of a class and non-members. For instance, we may say: • Tom is tall because his height is 181 cm. If we drew a line at 180 cm, we would find that David, who is 179 cm, is small. Is David really a small man or we have just drawn an arbitrary line in the sand? • Fuzzy logic reflects how people think. It attempts to model our sense of words, our decision making and our common sense. As a result, it is leading to new, more human, intelligent systems.
Fuzzy, or multi-valued logic was introduced in the 1930s by Jan Lukasiewicz, a Polish philosopher. While classical logic operates with only two values 1 (true) and 0 (false). • Lukasiewicz introduced logic that extended the range of truth values to all real numbers in the interval between 0 and 1. He used a number in this interval to represent the possibility that a given statement was true or false. • For example, the possibility that a man 181 cm tall is really tall might be set to a value of 0.86. It is likely that the man is tall. This work led to an inexact reasoning technique often called possibility theory.
Later, in 1937, Max Black published a paper called “Vagueness: an exercise in logical analysis”. • In this paper, he argued that a continuum implies degrees. • Max Black stated that if a continuum is discrete, a number can be allocated to each element. He accepted vagueness as a matter of probability.
In 1965 Lotfi Zadeh, published his famous paper “Fuzzy sets”. • Zadeh extended the work on possibility theory into a formal system of mathematical logic, and introduced a new concept for applying natural language terms. • This new logic for representing and manipulating fuzzy terms was called fuzzy logic, and Zadeh became the Master of fuzzy logic.
Why fuzzy? As Zadeh said, the term is concrete, immediate and descriptive; we all know what it means. However, many people in the West were repelled by the word fuzzy, because it is usually used in a negative sense. • Why logic? Fuzziness rests on fuzzy set theory, and fuzzy logic is just a small part of that theory.
Fuzzy logic is a set of mathematical principles for knowledge representation based on degrees of membership. Unlike two-valued Boolean logic, fuzzy logic is multi-valued. It deals with degrees of membership and degrees of truth. Fuzzy logic uses the continuum of logical values between 0 (completely false) and 1 (completely true). Instead of just black and white, it employs the spectrum of colours, accepting that things can be partly true and partly false at the same time.
Fuzzy sets • The concept of a set is fundamental to mathematics. • However, our own language is also the supreme expression of sets. For example, car indicates the set of cars. When we say a car, we mean one out of the set of cars.
Crispset theory is governed by a logic that uses one of only two values: true or false. This logic cannot represent vague concepts. • The basic idea of the fuzzy set theory is that an element belongs to a fuzzy set with a certain degree of membership. Thus, a proposition is not either true or false, but may be partly true (or partly false) to any degree. This degree is usually taken as a real number in the interval [0,1].
The classical example in fuzzy sets is tall men. The elements of the fuzzy set “tall men” are all men, but their degrees of membership depend on their height.
The x-axis represents the universe of discourse the range of all possible values applicable to a chosen variable. In our case, the variable is the man height. According to this representation, the universe of men’s heights consists of all tall men. • The y-axis represents the membership value of the fuzzy set. In our case, the fuzzy set of “tall men” maps height values into corresponding membership values.
A fuzzy set is a set with fuzzy boundaries. • Let X be the universe of discourse and its elements be denoted as x. In the classical set theory, crisp set A of X is defined as function fA(x)called the characteristic function of A • fA(x): X {0, 1}, where This set maps universe X to a set of two elements. For any element x of universe X, characteristic function fA(x) is equal to 1 if x is an element of set A, and is equal to 0 if x is not an element of A.
In the fuzzy theory, fuzzy set A of universe X is defined by function A(x) called the membership function of set A • A(x): X [0, 1], where A(x) = 1 if x is totally in A; • A(x) = 0 if x is not in A; • 0 < A(x) < 1 if x is partly in A. This set allows a continuum of possible choices. For any element x of universe X, membership function A(x) equals the degree to which x is an element of set A. This degree, a value between 0 and 1, represents the degree of membership, also called membership value, of element x in set A.
How to represent a fuzzy set in a computer? • First, we determine the membership functions. In our “tall men” example, we can obtain fuzzy sets of tall, short and average men. • The universe of discourse the men’s heights consists of three sets: short, average and tall men. As you will see, a man who is 184 cm tall is a member of the average men set with a degree of membership of 0.1, and at the same time, he is also a member of the tall men set with a degree of 0.4.
Representation of crisp and fuzzy subsets Typical functions that can be used to represent a fuzzy set are sigmoid, gaussian and pi. However, these functions increase the time of computation. Therefore, in practice, most applications use linear fit functions.
Linguistic variables and hedges • A linguistic variable is a fuzzy variable. For example, the statement “John is tall” implies that the linguistic variable John takes the linguistic value tall.
In fuzzy expert systems, linguistic variables are used in fuzzy rules. For example: IF wind is strong THEN sailing is good IF project_duration is long THEN completion_risk is high IF speed is slow THEN stopping_distance is short
The range of possible values of a linguistic variable represents the universe of discourse of that variable. • For example, the universe of discourse of the linguistic variable speed might have the range between 0 and 220 km/h and may include such fuzzy subsets as very slow, slow, medium, fast, and very fast. • A linguistic variable carries with it the concept of fuzzy set qualifiers, called hedges. • Hedges are terms that modify the shape of fuzzy sets. They include adverbs such as very, somewhat, quite, more or less and slightly.
Operations of fuzzy sets The classical set theory developed in the late 19th century by Georg Cantor describes how crisp sets can interact. These interactions are called operations.
Complement • Crisp Sets:Who does not belong to the set? • Fuzzy Sets:How much do elements not belong to the set? • The complement of a set is an opposite of this set. • For example, if we have the set of tall men, its complement is the set of NOT tall men. When we remove the tall men set from the universe of discourse, we obtain the complement. • If A is the fuzzy set, its complement A can be found as follows: • A(x) = 1 A(x)
Containment • Crisp Sets:Which sets belong to which other sets? • Fuzzy Sets:Which sets belong to other sets? • Similar to a Chinese box, a set can contain other sets. The smaller set is called the subset. • For example, the set of tall men contains all tall men; very tall men is a subset of tall men. However, the tall men set is just a subset of the set of men. • In crisp sets, all elements of a subset entirely belong to a larger set. In fuzzy sets, however, each element can belong less to the subset than to the larger set. Elements of the fuzzy subset have smaller memberships in it than in the larger set.
Intersection • Crisp Sets:Which element belongs to both sets? • Fuzzy Sets: How much of the element is in both sets? • In classical set theory, an intersection between two sets contains the elements shared by these sets. • For example, the intersection of the set of tall men and the set of fat men is the area where these sets overlap. • In fuzzy sets, an element may partly belong to both sets with different memberships. A fuzzy intersection is the lower membership in both sets of each element. • The fuzzy intersection of two fuzzy sets A and B on universe of discourse X: • AB(x) = min [A(x), B(x)] = A(x) B(x),
Union • Crisp Sets:Which element belongs to either set? • Fuzzy Sets: How much of the element is in either set? • The union of two crisp sets consists of every element that falls into either set. • For example, the union of tall men and fat men contains all men who are tall OR fat. • In fuzzy sets, the union is the reverse of the intersection. That is, the union is the largest membership value of the element in either set. • The fuzzy operation for forming the union of two fuzzy sets A and B on universe X can be given as: • AB(x) = max [A(x), B(x)] = A(x) B(x),
Fuzzy rules In 1973, Lotfi Zadeh published his second most influential paper. This paper outlined a new approach to analysis of complex systems, in which Zadeh suggested capturing human knowledge in fuzzy rules.
What is a fuzzy rule? A fuzzy rule can be defined as a conditional statement in the form: IF x is A THEN y is B where x and y are linguistic variables; and A and B are linguistic values determined by fuzzy sets on the universe of discourses X and Y, respectively.
What is the difference between classical and fuzzy rules? A classical IF-THEN rule uses binary logic, for example, Rule: 1 IF speed is > 100 THEN stopping_distance is long Rule: 2 IF speed is < 40 THEN stopping_distance is short The variable speed can have any numerical value between 0 and 220 km/h, but the linguistic variable stopping_distance can take either value long or short. In other words, classical rules are expressed in the black-and-white language of Boolean logic.
We can also represent the stopping distance rules in a fuzzy form: Rule: 1 IF speed is fast THEN stopping_distance is long Rule: 2 IF speed is slow THEN stopping_distance is short In fuzzy rules, the linguistic variable speed also has the range (the universe of discourse) between 0 and 220 km/h, but this range includes fuzzy sets, such as slow, medium and fast. The universe of discourse of the linguistic variable stopping_distance can be between 0 and 300 m and may include such fuzzy sets as short, medium and long.
Fuzzy sets of tall and heavy men These fuzzy sets provide the basis for a weight estimation model. The model is based on a relationship between a man’s height and his weight: IF height is tall THEN weight is heavy
The value of the output or a truth membership grade of the rule consequent can be estimated directly from a corresponding truth membership grade in the antecedent. This form of fuzzy inference uses a method called monotonic selection.
A fuzzy rule can have multiple antecedents, for example: IF project_duration is long AND project_staffing is large AND project_funding is inadequate THEN risk is high IF service is excellent OR food is delicious THEN tip is generous
The consequent of a fuzzy rule can also include multiple parts, for instance: IF temperature is hot THEN hot_water is reduced; cold_water is increased